Lectures related to Basic concepts: digital elevation model

Digital Elevation Models: Basic Element

Explores the role of relief in modeling Earth's surface phenomena and the advancements in technology for producing precise digital elevation models.

Coordinates and Projection Systems

Covers observation scales, coordinate systems, geoid, and projection systems in GIS.

Digital Elevation Models: Basic Concepts

Covers methods for sampling elevation and measuring elevation using leveling, photogrammetry, and LiDAR in Geographic Information Systems.

Digital Elevation Models: Basic Elements

Covers digital elevation models, altitude acquisition methods, representation techniques, and relief visualization using shading and contour lines.

Geodetic Concepts: Reference Systems and Projections

Covers geodetic concepts, reference systems, and map projections for accurate measurements in engineering projects.

Additional Transformations from/to ECEF

Explores additional transformations between geocentric and geodetic systems, map projections, and vertical reference systems.

Geodesy Bases: Coordinate Systems, Geoid, and Ellipsoid

Explores geodesy basics, covering coordinate systems, geoid, and ellipsoid representations on a flat plane.

Geoid References: Geoid

Explores the geoid, gravity conditions, geoid elevation, and reference systems.

Coordinates and Projection Systems

Covers principles of transposing spatial entities, scales, coordinate systems, projection systems, and EPSG codes.

Geographic Information Systems: Data Acquisition and Representation

Explores Geographic Information Systems, covering data acquisition, representation, and visualization of geodata.

Geodesy Bases and Coordinate Systems

Explores geodesy bases, coordinate systems, and projections for astronomy and navigation.

Basic Elements of Altitude Models

Covers methods for acquiring and representing altitude data, emphasizing the historical and analytical importance of relief.

Spatial Phenomena: Isovalues

Covers isovalue curves in geographic information systems and their creation using QGIS.

Spatial Analysis Processes: Modeling and Essentials

Covers spatial analysis processes, including modeling and essentials.

Geodesy Fundamentals: Understanding Earth Reference Systems

Provides an overview of geodesy, focusing on Earth's reference systems and the importance of accurate geodetic data for practical applications.

Geodetic References: Coordinates and Systems

Explores geodetic references, coordinate systems, the geoid, and reference systems for accurate measurements.

Interactions between Data Layers: Raster-Vecteur

Covers interactions between raster and vector data layers in GIS using QGIS tools.

Coordinate Transformation and Satellite Tracking

Explores coordinate transformation, satellite tracking, GPS signals, and receiver systems, including practical exercises and study of scientific articles.

Spatial Autocorrelation and Dependence

Covers spatial autocorrelation, spatial dependence, biases in classical statistics, and limitations of statistical tools in geography.

Spatial Analysis: Spatial Statistics and Analysis

Explores spatial statistics, digital elevation models, land cover analysis, and geographically weighted regression in spatial analysis.